Effects of Oxygen Ratio on the Properties of Tin Oxide Thin Films Doped with Bismuth

Abstract: This study examins the effects of the oxygen ratio on the properties of bismuth (Bi)‐doped tin oxide (Bi‐SnOx) films deposited by radio frequency magnetron sputtering using a SnO (90 at%)‐Bi (10 at%) ceramic target. The properties of the samples are characterized by X‐ray photoelectron spectroscopy (XPS), Hall effect measurements, dynamic‐secondary ion mass spectrometry (D‐SIMS), and X‐ray diffraction (XRD). The samples deposited without oxygen gas exhibit Sn4+ and Sn2+ XPS peak areas of 44.7 and 41.1%, respec… Show more

“…For the Sn 3d XPS spectra ( Figure 2 a ), the two peaks of Sn 3d 5/2 and 3d 3/2 in pristine SnO 2 shifted from 487.2 and 495.6 eV to the higher binding energies of 487.6 and 496.1 eV, with the spin–orbit splitting energy of 8.4 eV. [ 18 ] The higher binding energy of Sn 3d indicates more Sn (II)’s conversion to Sn (IV), [ 16 , 19 ] potentially widening the band gap and decreasing the number of oxygen vacancies. [ 20 , 21 ] In terms of O 1s spectra (Figure 2b ), two peaks of around 532.5 and 531.1 eV refer to the hydroxyl group (–OH) on the SnO 2 surface and the saturated lattice oxygen in SnO 2 film, respectively.…”

Periodic Acid Modification of Chemical‐Bath Deposited SnO₂ Electron Transport Layers for Perovskite Solar Cells and Mini Modules

“…For the Sn 3d XPS spectra ( Figure 2 a ), the two peaks of Sn 3d 5/2 and 3d 3/2 in pristine SnO 2 shifted from 487.2 and 495.6 eV to the higher binding energies of 487.6 and 496.1 eV, with the spin–orbit splitting energy of 8.4 eV. [ 18 ] The higher binding energy of Sn 3d indicates more Sn (II)’s conversion to Sn (IV), [ 16 , 19 ] potentially widening the band gap and decreasing the number of oxygen vacancies. [ 20 , 21 ] In terms of O 1s spectra (Figure 2b ), two peaks of around 532.5 and 531.1 eV refer to the hydroxyl group (–OH) on the SnO 2 surface and the saturated lattice oxygen in SnO 2 film, respectively.…”

Periodic Acid Modification of Chemical‐Bath Deposited SnO₂ Electron Transport Layers for Perovskite Solar Cells and Mini Modules

“…† No deconvolution was needed for the CBD samples (15-SnO 2 , 30-SnO 2 , 45-SnO 2 ). All of the peaks have binding energies close to 486.6 eV, 25 likely suggesting the full conversion of Sn 2+ from the precursor into Sn 4+ . To conrm this, XPS of commercial SnO 2 powder was also performed, which showed similar peak energies (Fig.…”

“…Instead, only enough was etched to ensure that region is non-conductive. Fortunately, these peaks have binding energies closer to Sn 2+ (486 eV) 25 rather than Sn 4+ , so the fact that the coated samples seem to comprise only Sn 4+ shows that Sn 3d contributions from the uncoated glass are likely to be negligible, despite the lack of 100% SnO 2 coverage on all sonicated lms (as shown in Fig. 2b).…”

Enabling a rapid SnO₂ chemical bath deposition process for perovskite solar cells

“…Band gap of SnO films for its different tin and oxygen ratio have been extracted by Tauc plot as shown in the figure 6 (b). From figure , it is observed that band gap increases with an increase in the Sn:O ratio, which is mainly due to the fact that with an increase in oxygen ratio of SnO film, its properties highly tends to toward the SnO 2 (Tin-dioxide) nature [12], [22], [23]. We extended the experimental study further to investigate the electrical parameters of SnO films for its different composition of Sn and O ratios using Hall measurement in order to find out nature of SnO films, its carrier concentration, Hall mobility and sheet resistivity using equations given below.…”

Experimental Investigation and DFT Study of Tin-Oxide for Its Application as Light Absorber Layer in Optoelectronic Devices